KR20010111163A - 1530㎚-band pumped l-band erbium doped fiber amplifier - Google Patents

Abstract

Without significant change in noise characteristics The present invention relates to a long-wavelength erbium-doped optical fiber amplifier excited by an excitation light source having a 1530 nm wavelength band with improved gain characteristics. A wavelength division multiplexing coupler for coupling the excitation light source and the input optical signal, and an erbium-added optical fiber for amplifying the input optical signal in an inverted state having a high energy level by the excitation light source, wherein the excitation unit The excitation light source of 1530 nm wavelength band is characterized by using any one of a forward excitation in the same direction as the input signal light, a reverse excitation in the opposite direction, a bidirectional excitation using a forward excitation and a reverse excitation, or a two-stage amplifying structure.

Description

Long-wavelength erbium-doped fiber amplifiers excited with light sources in the 1530-nm wavelength band {1530nm-BAND PUMPED L-BAND ERBIUM DOPED FIBER AMPLIFIER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to optical communication system devices, and more particularly, to a long wavelength band erbium-doped fiber amplifier (EDFA) having gain in a longer wavelength band of 1570 nm wavelength band or more using an Erbium doped fiber amplifier (EDFA).

Recently, large-capacity transmission systems are progressing due to the rapid increase in the amount of information at home and abroad. In particular, by using optical wavelengths of multiple channels, wavelength division multiplexing that effectively utilizes the wide bandwidth provided by optical fibers. Hereinafter, the transmission scheme by 'WDM' has attracted high attention.

An optical amplifier (OA) is a key element in a communication network using such a WDM transmitter. The optical amplifier (OA) is an apparatus for amplifying an optical signal without photoelectric conversion. The optical amplifier (OA) can easily compensate for the transmission loss of the optical fiber and the splitting loss of the distribution network. The optical amplifier erbium using the optical fiber to which the rare earth metal erbium is added Erbium-Doped Fiber Amplifier (EDFA) is widely used.

The EDFA is used as an optical power amplifier and an optical repeater in optical communication because it can amplify an optical signal with a high gain over a wide wavelength range of 1.52 탆 to 1.63 탆 wavelength band with the smallest transmission loss. In particular, since optical signals of different wavelengths can be amplified almost at once without crosstalk, they are very useful for the WDM method. Therefore, it is becoming a key element of the WDM-based super-capacity transmission network or subscriber optical communication system.

In general, EDFA uses an erbium-doped fiber (EDF), an optical amplification medium, an optical pump light source (PL) for exciting the added erbium ions, a light source having an input signal light wavelength and a pump light wavelength. Wavelength splitting multiplexer (WDM) for separating or combining, respectively, and an optical isolator (ISO) for passing the light source going in the forward direction and blocking the light source going in the reverse direction. When the pump light enters the EDF from the pump light source through the WDM, the erbium ions in the EDF are excited, and the signal light is amplified while the excited erbium ions transition to a low energy state while the input signal light travels along the EDF. Here, a light source having a wavelength range of 800 nm, 980 nm, and 1480 nm is mainly used as the excitation light source PL, and the characteristics of EDFA are greatly influenced by the excitation light source PL. EDFA is a noise figure that shows how much the gain (G), which is used as a measure of how much the input optical signal is amplified, and how the ratio of signal / noise (S / N) is deteriorated. The characteristic is expressed.

The gain and noise figure are greatly influenced by what wavelength band excitation light source is used and by what excitation structure. The excitation light source has a laser diode of 1480 nm wavelength (LD) and a 980 nm wavelength band. Titanium: sapphire (Ti: sapphire) was studied in 1989, and the two wavelength bands have since been used as the wavelengths of the most common excitation light sources.

The excitation method is determined according to the direction of the input signal light and the excitation light source. If the traveling direction is the same, it is called a forward pump, otherwise it is called a backward pump. Here it is. In particular, forward excitation favors the reduction of the noise figure and reverse excitation favors the gain, so they are an important design element of EDFA. Here, bidirectional excitation improves the performance of the EDFA by using an excitation light source of the same wavelength, or by using two different excitation light sources of 980 nm wavelength band in the forward direction and 1480 nm wavelength band in the reverse direction.

These EDFAs have been mainly used to amplify signals in the 1550 nm wavelength band, but due to the need for expansion of the amplification band and increasing the transmission capacity and the nonlinear phenomena when using dispersion shifted fibers (DSFs), the EDFA has been used to amplify signals of more than 1570 nm wavelength. Long-wavelength EDFA (L-band EDFA) has emerged.

Compared to the long-wavelength EDFA, the EDFA of the conventional 1550 nm wavelength band is called a C-band EDFA, and there is no difference between the two in this method, but since the long-wavelength EDFA uses a density inversion state of about 40%, the C-band EDFA and In comparison, the length of the EDF is about 5 to 10 times longer.

Looking at the prior art that implements the EDFA as described above, using the LD as the excitation light source, instead of the WDM fusion coupling (fusion coupling) of the two optical fibers (ED) was configured using the EDFA, Ring (application) Lasers of structure have also been shown to be possible (US Pat. No. 4,955,025). Here's a description of the structure, By using 980nm LD as the forward excitation light source and 1480nm LD as the reverse excitation light source, the bidirectional excitation structure was proposed to reduce the noise figure of the optical amplifier in the 1530-1570nm wavelength band and improve the gain characteristics (US Patent 5,140,456).

As another conventional technique, an EDFA of a long wavelength band using 1550 nm LD as an auxiliary excitation light with 980 nm LD has been proposed to improve the conversion efficiency of an optical fiber amplifier of 1570-1600 nm wavelength band using EDF to the signal strength of excitation intensity. (R. Di Muro, NEJolley, J. Mun, "Measurement of the quantum efficiency of long wavelength EDFAs with and without an idler signal" ECOC'98 technical digest, 20-24p, sep. 1998).

The prior art as described above relates to the general structure of an EDF and an optical fiber amplifier using the same, or to mention a wavelength characteristic or structure of a WDM that uses 980 nm LD and 1480 nm LD but combines an input signal and an excitation wavelength. 1550nm LD is used as an auxiliary excitation of 980nm LD and 1480nm LD, but gain improvement is about 10%. It is limited to improve gain characteristics of power conversion efficiency (PCE) and optical amplifier of long wavelength band. There is.

The present invention has been made to solve the above problems of the prior art, by using the 1530nm wavelength band as an excitation light source for amplifying the input light of the long wavelength band (1570 ~ 1600nm) in the erbium-doped fiber amplifier (EDFA), An object of the present invention is to provide a long-wavelength erbium-doped fiber amplifier suitable for increasing the input strength conversion efficiency (PCE) to improve the gain efficiency of a long-wavelength input signal.

Another object of the present invention is to adopt a bidirectional excitation structure or a two-stage amplification structure using a 1530 nm wavelength band excitation light source, which is suitable for reducing noise characteristics and improving gain characteristics compared to only forward pumping of 1530 nm wavelength band. Provided is a band erbium-doped fiber amplifier.

1 is a configuration diagram of a long wavelength band EDFA that is forward excited using an excitation light source having a wavelength of 1530 nm according to a first embodiment of the present invention;

2A is a configuration diagram of a 1530 nm wavelength band excitation light source implemented using a two-stage amplifying structure and an optical variable filter;

2b is a configuration diagram of a 1530 nm wavelength band excitation light source implemented using a two-stage amplifying structure, an optical cycler, and an optical fiber grating;

2c is a block diagram of an excitation light source having a wavelength of 1530 nm implemented using a laser diode and an optical fiber grating;

3 is a diagram showing the configuration of a long wavelength band EDFA having a bidirectional excitation structure using reverse excitation of 1530 nm wavelength band and forward excitation of 980 nm wavelength band;

4 is a diagram showing the configuration of a long wavelength band EDFA comprising a first amplifier stage in which an excitation light source of 980 nm wavelength band is forward-excited and a second amplifier stage in which excitation light sources of 1530 nm wavelength band are forward and reversely excited;

5 is a spectrum of an excitation light source having a wavelength of 1530 nm using an optical variable filter (OTF) and an optical fiber grating (FBG),

6 is a graph of wavelength dependency characteristic of insertion loss (N.F) of an excitation light source and an input signal light source of a wavelength division multiplexer (WDM);

FIG. 7 is a graph illustrating gain (G) and noise figure (N.F.) for each wavelength of long wavelength band EDFA excited with an excitation light source having a wavelength of 1530 nm;

8 is a comparison diagram according to the excitation wavelength of the excitation intensity required to obtain a uniform gain of 15 dB in the long wavelength band,

9 is a graph showing a change in gain according to a wavelength change of an excitation light source having a wavelength of 1530 nm in terms of an input signal;

FIG. 10 shows gain and noise figure of long wavelength band EDFA excited with excitation light source of 1530 nm wavelength band when 5-channel signal is input; FIG.

* Description of the symbols for the main parts of the drawings *

10: input terminal 20: excitation portion of 1530 nm wavelength band

30: WDM combiner 40: EDF

50: Optical Spectrum Analyzer (OSA) 61,62: Advertiser

70: wavelength variable light source (TLS) 80: optical variable filter (OTF)

90: optical circulator 91: optical fiber grating (FBG)

100a: first amplifier stage 200a: second amplifier stage

A first embodiment of the present invention for achieving the above object is an optical fiber amplifier comprising: an input terminal to which an optical signal of a long wavelength band is input; an excitation unit for exciting an excitation light source of 1530 nm wavelength band; combining the excitation light source and the input optical signal And an erbium-doped optical fiber which amplifies the input optical signal in an inverted state having a high energy level by the excitation light source, wherein the excitation portion is used to change the wavelength of the excitation light source. A wavelength tunable light source, a laser diode in a 980 nm wavelength band that excites an excitation light source in a 980 nm wavelength band, a first forward wavelength division multiplexer coupling the wavelength variable excitation light source, and an excitation coupled in the first wavelength division multiplexer A first amplifier stage comprising a first erbium-doped optical fiber for amplifying a light source; And a first 1480 nm wavelength laser diode that excites an excitation light source in a 1480 nm wavelength band, a second forward wavelength division multiplexing combiner for coupling the excitation light source, and a second 1480 nm wavelength laser diode that excites an excitation light source in a 1480 nm wavelength band. And a reverse third wavelength division multiplexer for coupling the excitation light sources excited from the laser diode of the second 1480 nm wavelength band, a second erbium-doped optical fiber for amplifying the forward and reverse excitation light sources, and the second erbium-doped optical fiber. And a second amplifying stage including an optical variable filter for removing the amplified self-emitting noise light among the output amplified lights and outputting only the amplified light to the output stage.

The second embodiment of the present invention is an input terminal to which an optical signal of a long wavelength band is input, a laser diode of a 980 nm wavelength band which outputs an excitation light source of a 980 nm wavelength band in a forward direction, and a forward direction of combining the input optical signal and the excitation light source by wavelength division multiplexing and combining the same. A first wavelength division multiplexing combiner, a laser diode of 1530 nm wavelength band that outputs an excitation light source having a wavelength of 1530 nm in a reverse direction, a reverse second wavelength division multiplexing combiner for wavelength division multiplexing and combining the reverse excitation light source, and the forward and reverse excitation light sources An erbium-doped optical fiber for amplifying the input optical signal in an inverted state having a high energy level, an optical spectrum analyzer for analyzing the spectrum of the amplified optical signal, and the input terminal for preventing noise due to reflection of the signal. A first wavelength division multiplexer, and a second wavelength division multiplexer Characterized by further comprising: an advertisement for yirueojim rib connected between the spectrum analyzer.

According to a third embodiment of the present invention, an optical amplifier having a two-stage amplifying structure includes: an input terminal to which an optical signal is input, a laser diode of 980 nm wavelength band for generating an excitation light source of 980 nm wavelength band, and wavelength division of the input optical signal and the excitation light source A first wavelength division multiplexing combiner for multiplexing and combining, a first amplifying stage comprising a first erbium-doped optical fiber for amplifying the optical signal multiplexed in the first wavelength division multiplexer; And a forward first laser diode for generating an excitation light source having a wavelength of 1530 nm, a forward second wavelength division multiplexing coupler for coupling an amplified light source amplified by the first erbium-doped optical fiber with an excitation light source having a wavelength of 1530 nm, A reverse second laser diode generating an excitation light source having a 1530 nm wavelength band, a reverse third wavelength division multiplexing combiner combining the reverse excitation light source with a 1530 nm wavelength band, and amplifying the forward excitation light source and a reverse excitation light source; And a second amplifying stage made of 2 erbium-doped optical fibers.

Hereinafter, the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. .

FIG. 1 is a block diagram illustrating a long wavelength band EDFA that is forward excited using an excitation light source having a wavelength of 1530 nm, and follows a forward excitation configuration, which simplifies the factors influencing the characteristics of the EDFA and is dependent on the wavelength difference of the excitation light source. This is to effectively implement the bay.

As shown in FIG. 1, the first embodiment of the present invention provides an input terminal 10 into which an optical signal having a long wavelength band (1570 to 1600 nm) is input, an excitation portion 20 for exciting an excitation light source having a wavelength of 1530 nm in a forward direction, A WDM coupler 30 for coupling the input optical signal and an excitation light source, an EDF 40 for amplifying the input light in an inverted state having a high energy level by the excitation light source, and the amplified light Optical Spectrum Analyzer (OSA) (50) for analyzing the spectrum of the signal, the input terminal 10, WDM combiner 30, EDF (40) and optical to prevent noise caused by the reflection of the signal It consists of an optical isolator (60a, 60b) connected between the spectrum analyzer (OSA) (50).

The optical amplifier of the first embodiment is an optical amplifier having a forward pumping structure, and an optical signal having a wavelength of 1570 to 1600 nm input to the input terminal 10 has a wavelength of 1530 nm excited from the excitation unit 20. After being coupled by the excitation light source and the forward WDM combiner 30 for the 1530 nm wavelength band, the signal is inserted into the 65 m EDF 40 and amplified and the signal amplified by the EDF 40 is measured by the optical spectrum analyzer 50. do.

At this time, the WDM combiner 30 has a large insertion loss (Insertion Loss) of the wavelength insertion portion of the excitation light source in the wavelength band of the input signal light source so that the wavelength noise of the excitation light source does not affect the characteristics of the long wavelength band EDFA. To be designed.

Since the long wavelength band EDFA according to the first embodiment uses a low density inversion state of about 40%, it is possible to absorb light in the 1530 nm wavelength band, and furthermore, the use of light in the 1530 nm wavelength band enables reverse self-emission of EDFA. Since the noise light (ASE) can be suppressed, the input intensity conversion efficiency (PCE) is twice as efficient as the excitation light in the 1480 nm wavelength band.

2A to 2B show an excitation portion of FIG. 1, and generate an excitation light source having a wavelength of 1530 nm using a two stage amplifier structure.

As shown in FIG. 2A, the first amplification stage 100 includes a tunable light source (TLS) 70 capable of changing the wavelength of the excitation light source and a 980 nm wavelength band that excites an excitation light source of the 980 nm wavelength band. LD 21, a forward first WDM coupler (WDM1) 31 for coupling the wavelength-variable excitation light source, and a first EDF 41 for amplifying the excitation light source coupled in the first WDM combiner 31. The second amplification stage 200 includes a first LD 22a of a first 1480 nm wavelength band that excites an excitation light source having a wavelength of 1480 nm, a second forward WDM combiner (WDM2) 32 that combines the excitation light source, and a 1480 nm wavelength band. A third WDM coupler (WDM3) 33 for coupling an excitation light source excited from the LD 22b of the second 1480 nm wavelength band for exciting the excitation light source of the second 1480 nm wavelength band, and the forward direction A second EDF 42 for amplifying the excitation light source and the reverse excitation light source, to remove the amplified self-emitting noise light Comprising an optical variable filter (OTF) for the 80, the advertisement for preventing noise caused by the reflection of the signal between the first amplifier stage 100, the second amplifier stage 200, the second amplifier stage 200 and the output stage It further comprises a lip machine (63, 64).

The two-stage amplifying structure as described above enables a high output excitation light source, changes the wavelength of the excitation light source using the wavelength variable light source (TLS) 70, and the first EDF 41 of the first amplification stage 100 is It is excited by the LD 21 of the 980 nm wavelength band and the forward first WDM combiner 41, and the second EDF 42 of the second amplifier stage 200 is the LD 22a of the 1480 nm wavelength band and the forward second WDM ( 32) are bidirectionally excited by the LD 22b in the 1480 nm wavelength band and the reverse second WDM 33. At this time, the wavelength variable light source (TLS) 70 is composed of laser light and amplified self emission (ASE) noise light, the latter of which is unnecessary noise light by the two-stage amplifier with the laser light. After being amplified, it remains in the wavelength range of 1560 nm or more while maintaining the intensity of about -20 dBm. The light of the wavelength of the noise light of the excitation light source is blocked so that the noise light of the amplified excitation light source does not go to the output terminal together with the laser light of the amplified excitation light, and the light is variable to transmit the light of the wavelength band of the laser light of the amplified excitation light. An Optical Tunable Filter (OTF) 80 is used.

FIG. 2B is a view showing another configuration of the excitation portion of FIG. 1, and instead of the optical variable filter 80 of FIG. 2A, an optical circulator 90 and an optical bragg grating (FBG) 91a are used. I use it. At this time, when the optical signal amplified from the second EDF 42 is input, the optical circulator 90 is output to the optical fiber Bragg grating (FBG) without reflection or attenuation, and the optical fiber Bragg grating (FBG) 91a. Reflects only the wavelength of the excitation light, thereby eliminating amplified self-emission (ASE) noise light.

Here, the optical fiber grating is a reflective filter element having a large reflectance at a specific wavelength, and most of the unreflected light transmits without loss. It is an element type which is highly desirable in optical communication systems and devices, such as easy and very small connection loss, which is likely to be mass produced at low cost.

As described above, a reflective filter such as an FBG having a maximum reflectance at the Bragg wavelength and hardly reflecting at other wavelengths or a dielectric thin film filter having the same transmission / reflection characteristics as the optical fiber grating is attached to the excitation light output end side. Thus, the amplified self-emitting noise light can be effectively removed.

FIG. 2C shows a forward pumping structure using LD of 1530 nm wavelength band as an excitation light source of 1530 nm wavelength band.

As shown in FIG. 2C, an input terminal 11 into which an optical signal is input, an LD 23 in a 1530 nm wavelength band that outputs an excitation light source in a 1530 nm wavelength band, and a forward WDM combiner 34 coupling the input optical signal and an excitation light source ), An EDF (43) for amplifying the input optical signal in an inverted state having a high energy level by the excitation light source, and an optical spectrum analyzer (OSA) (51) for analyzing the spectrum of the amplified optical signal. And an optical isolator (65,66) connected between the input terminal 11, the WDM combiner 34, the EDF 43, and the optical spectrum analyzer 51 to prevent noise caused by the reflection of the signal. It is composed of

In this case, a single wavelength oscillation LD having an FBG 91b is preferable to improve wavelength characteristics, and a general Faberiferro laser diode (FP LD) having a wide oscillation line width may be used as an excitation light source having a wavelength of 1530 nm. In this case, the peak wavelength is placed close to the 1530 nm wavelength to prevent the noise figure from deteriorating. Then, the insertion loss of the excitation wavelength of the WDM combiner 30 is designed to increase rapidly from the 1540 nm wavelength band. Here, the FBG 91a of FIG. 2B is simply used for the purpose of reflection, whereas the FBG 91b of FIG. 2C is used for the purpose of lowering the reflectivity to enable the laser diode to laser in the Bragg wavelength band.

3 shows a long wavelength band EDFA according to a second embodiment of the present invention, and shows a bidirectional excitation structure.

As shown in FIG. 3, an input terminal 12 into which an optical signal is input, an LD 24 of a 980 nm wavelength band that outputs an excitation light source having a 980 nm wavelength band in a forward direction, and a wavelength division multiplexing combination of the input optical signal and an excitation light source A forward first WDM combiner 35, an LD 25 of a 1530 nm wavelength band that outputs an excitation light source having a wavelength of 1530 nm in the reverse direction, a reverse second WDM combiner 36 which combines the reverse excitation light source by wavelength division multiplexing, and An EDF 44 for amplifying the input optical signal in an inverted state having a high energy level by the forward and reverse excitation light sources, and an optical spectrum analyzer (OSA; OSA) 52 for analyzing the spectrum of the amplified optical signal; Advertisers 67 and 68 connected between the input terminal 12, the first WDM combiner 35, the second WDM combiner 36, and the optical spectrum analyzer 52 to prevent noise caused by reflection of the signal. It is composed of

By using the bidirectional excitation structure as described above, the noise characteristic of the long wavelength band EDFA can be lowered and the gain characteristic can be greatly improved.

4 is a diagram illustrating a long wavelength band optical amplifier of a two-stage amplifying structure according to a third embodiment of the present invention. The first amplifier stage 100a generates an input terminal 13 through which an optical signal is input and an excitation light source having a wavelength range of 980 nm. LD (26) having a wavelength band of 980nm, the first WDM coupler (WDM1) (37) for coupling the wavelength and multiplexing the input optical signal and the excitation light source is amplified by the optical signal coupled from the first WDM combiner (37) The first EDF (45), the second amplifier stage (200a) is an excitation light source (27a) of the first 1530nm wavelength band for generating an excitation light source of 1530nm wavelength band, a forward second WDM combiner for coupling the excitation light source ( WDM2) 38, an excitation light source 27b in the second 1530 nm wavelength band for generating an excitation light source in the 1530 nm wavelength band, a reverse third WDM coupler (WDM3) 39 for coupling the excitation light source, and the forward excitation light source A second EDF 46 in which amplification of the signal light is caused by the reverse excitation light source, The group the first amplification stage 101 and second amplification stage 201 and second amplification stage ad granulator (69a, 69b) for preventing the noise due to reflection of the signal between 200 and output stage further includes.

The two-stage optical amplifier has a characteristic of lowering noise characteristics and increasing gain characteristics. The first EDF 45 of the first amplifying stage 100a includes the LD 26 and the first forward WDM combiner having a wavelength of 980 nm. 37, and the second EDF 46 of the second amplifying stage 201 is excited by the excitation light source 27a in the 1530 nm wavelength band, the forward WDM coupler 38 in the forward direction, and the excitation light source 27b in the 1530 nm wavelength band. It is bidirectionally excited by the reverse second WDM combiner 39.

As described above, the present invention shown in FIGS. 1, 3, and 4 is an excitation structure using a light source of 1530 nm wavelength band, and a bidirectional excitation structure using a excitation light source of 980 nm wavelength band or 1480 nm wavelength band in addition to forward excitation. By using the two-stage amplification structure, the noise characteristic can be lowered and the gain characteristic can be further improved.

FIG. 5 is a diagram showing a spectrum of an 1530 nm excitation light source implemented using a wavelength variable filter (OTF) and an optical fiber grating (FBG), where the transmission loss is 10 nm from the peak. ) Is large enough and there is no wavelength characteristic of the excitation light using the wavelength variable filter (OTF) or the excitation light using the optical fiber grating (FBG).

FIG. 6 is a graph showing wavelength-dependent characteristics of the insertion loss between the excitation light source and the input signal light source of the WDM combiner 30, and it can be seen that the excitation light source band and the signal light source band are well separated. However, since the insertion loss of the excitation light source starts to increase around 1565 nm, the excitation light source can pass through the WDM combiner 30 up to the 1560 nm wavelength band, and thus the ASE noise light of the excitation light source deteriorates the characteristics of the EDFA. An optical variable filter (OTF) is used in conjunction with WDM to suppress ASE noise of such excitation light sources. Therefore, when the wavelength selection characteristic of such a WDM coupler is designed more appropriately, it is not necessary to use the optical variable filter.

FIG. 7 illustrates the gain and noise figure of the long wavelength band EDFA excited in the 1530 nm wavelength band using the configuration of FIGS. 1 and 2, and has a 30 nm wavelength with a forward excitation of 44 mW. The band shows an even 15dB gain within 1dB error and the noise figure is 6.36dB at 1571.5nm.

FIG. 8 is a comparison diagram according to the excitation wavelength of the excitation intensity required to obtain a uniform gain of 15 dB in the long wavelength band, and from 1530 nm to 1530 nm to 1560 nm wavelength band at 3 nm intervals to investigate wavelength dependent characteristics of the excitation light source. The wavelength of the excitation light source was varied and the excitation intensity required to keep the gain uniformly 15 dB at 1571.5 to 1601.5 nm was measured. In addition, the experiment was performed after changing the wavelength of the excitation light to 1480 nm wavelength band in the same configuration as in FIG. 1 for comparison.

As a result, 74mW was required when excited in the 1480nm wavelength band, but had a value of 40mW around when excited in the 1530nm wavelength band. The excitation light source power (mW) that changes in the excitation wavelength (nm) can be expressed by the input intensity conversion efficiency (PCE).

PCE = (P _out -P _in ) / P _pump

As shown in Equation 1, P _out represents the intensity of the output signal light source, P _in represents the intensity of the input signal light source and P _pump represents the intensity of the excitation light source, and adjusts the excitation light source intensity to obtain a uniform gain. Excitation in the 1530 nm wavelength band (40 mW) is about twice as efficient as excitation in the 1480 nm wavelength band (74 mW).

However, when the wavelength of the excitation light increases above the 1550 nm wavelength band, two-level lasers have disadvantages, and the excitation light is not effectively used for inverting the density of the EDF, the excitation efficiency is deteriorated, and the noise figure rapidly increases. Done.

9 is a graph showing the change in gain according to the wavelength change of the excitation light source in the 1530 nm wavelength band from the viewpoint of the input signal, and four graphs for each measurement wavelength (1571 nm, 1581 nm, 1591 nm, and 1601 nm) are shown. In other words, it can be seen that the excitation wavelength band value for the highest gain moves toward the shorter wavelength as the excitation light intensity increases, which increases the density reversal as the excitation light intensity increases and increases the density wavelength in the long wavelength region of the 1530 nm wavelength band. This is because the absorption efficiency is reduced. The most significant meaning of FIG. 9 is that since the slope of the spectrum of the excitation wavelength is gentle on the short wavelength side and is steep on the long wavelength side, it is advantageous that the center wavelength is located at 1540 nm or less when the excitation light having a wide oscillation line width is used.

10 shows wavelength division multiplexing (WDM) of five channels. When the signal, that is, a signal of a plurality of channels divided by the wavelength in the transmission of the optical signal is input, the spectrum showing the gain and noise index of the long wavelength band EDFA excited to the 1530nm wavelength band, which is excited with a wavelength of 1533nm Results of amplification experiments of 5-channel WDM signals are shown. At this time, the experimental condition was used as a saturation signal (Saturation Tone) of 1590nm wavelength band, the probe (Probe) signal had a strength of -30 ~ -10 dBm. As a result, as in the small-signal amplification experiment, a uniform gain can be obtained within the bandwidth. For example, in the case of a 10 dBm input optical signal, a gain deviation within 0.1 dB is 26 nm and a range within 1 dB is 32 nm. A uniform gain of 13.5 dBm was obtained.

As described above, when the gain is obtained in the 1550 nm wavelength band by using an excitation light source of 1530 nm wavelength band, the 1480 nm wavelength band is the excitation light source closest to the wavelength of the input signal, but in the long wavelength band EDFA (L-band EDFA), By taking advantage of the fact that the gain occurs above the 1570 nm wavelength band and the density inversion at this time is about 40%, it is possible to take advantage of the fact that the 1530 nm wavelength band can be a light absorbing region rather than a light emitting region. There is a slight increase in noise, but the gain can be greatly improved.

In addition, as an excitation light source with a wavelength of 1530 nm, a wavelength band longer than 1560 nm using a light source having a narrow bandwidth using LD or an optical fiber Bragg grating (FBG) using a DFB structure or a wide bandwidth light source having a Fabry-Perot (FP) structure is used. By combining the two light sources by using WDM designed to make the intensity of the excitation light source incident to the EDF at -20 dB below the intensity of the input signal light source increases the noise of the input wavelength by the noise signal of the excitation light source. To prevent the phenomenon of reducing the characteristics.

Although the technical idea of the present invention has been described in detail according to the above preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

The long wavelength band EDFA excited by the 1530 nm wavelength band light source of the present invention described above can obtain an input intensity efficiency (PCE) about twice as large as that of the long wavelength band EDFA excited by the 1480 nm wavelength band light source, thereby improving the excitation efficiency of the EDFA. In addition, the bidirectional excitation structure in which the excitation light source in the 980 nm wavelength band or the 1480 nm wavelength band is reversed, and the excitation light source in the 1530 nm wavelength band is reversed, but the first stage amplification is the forward excitation using a 980 nm or 1480 nm wavelength light source, and the second stage is the 1530 nm wavelength. By using a two-stage amplifying structure that bidirectionally excites using a band light source, the noise characteristics of the long wavelength band EDFA can be lowered and the gain characteristics can be greatly improved.

Claims (12)

In the optical fiber amplifier, An input terminal to which an optical signal of a long wavelength band is input; An excitation portion for exciting excitation light sources in the 1530 nm wavelength band; A wavelength division multiplexer for coupling the excitation light source and the input optical signal; And Erbium-doped optical fiber for amplifying the input optical signal in an inverted state having a high energy level by the excitation light source Long wavelength band erbium-added optical fiber amplifier, characterized in that configured to include. The method of claim 1, The excitation light source is a long wavelength erbium-added optical fiber amplifier, characterized in that the output using a laser diode of 1530nm wavelength band. The method of claim 1, The excitation light source is a long-wavelength erbium-added optical fiber amplifier, characterized in that using a laser diode having a wavelength band of 1530nm reduced the bandwidth of the spectrum by the lattice structure formed on the optical fiber grating or the laser diode itself. The method of claim 1, The wavelength band range of the excitation light source is 1520 to 1560 nm, the long wavelength band erbium-added optical fiber amplifier. The method of claim 1, And the wavelength division multiplexing combiner is designed so that the insertion loss of the excitation light source is large in the wavelength band of the input optical signal. The method of claim 1, The input end is a long wavelength band Erbium-doped fiber amplifier, characterized in that the optical signal of 1570nm ~ 1630nm wavelength band is input. The method of claim 1, The excitation unit has a long wavelength band Erbium-doped fiber amplifier, characterized in that the excitation light source of the 1530 nm wavelength band uses any one of a forward excitation in the same direction as the input signal light, a reverse excitation in the opposite direction, or a bidirectional excitation in combination with the forward excitation and the reverse excitation. . The method of claim 7, wherein The bidirectional here, A long wavelength erbium-doped fiber amplifier characterized by consisting of a forward excitation using an excitation light source of 980 nm wavelength band or a 1480 nm wavelength band and a reverse excitation using an excitation light source of 1530 nm wavelength band. The method of claim 1, The excitation portion, A wavelength variable light source capable of changing the wavelength of the excitation light source, a laser diode of 980 nm wavelength band for exciting the excitation light source of the 980 nm wavelength band, a first forward wavelength division multiplexing combiner for coupling the wavelength-variable excitation light source, and the first wavelength A first amplifying stage including a first erbium-doped optical fiber for amplifying the excitation light source coupled in the split multiplexer; And A laser diode of a first 1480 nm wavelength band for exciting an excitation light source of a 1480 nm wavelength band, a second forward wavelength division multiplexing combiner for coupling the excitation light source, a laser diode of a second 1480 nm wavelength band for exciting an excitation light source of a 1480 nm wavelength band, A reverse third wavelength division multiplexer for coupling excitation light sources excited from the laser diode of the second 1480 nm wavelength band, a second erbium-doped optical fiber for amplifying the forward and reverse excitation light sources, and an output from the second erbium-doped fiber A second amplifying stage including an optical variable filter which removes the amplified self-emitting noise light among the amplified light and outputs only the amplified light to the output stage, And an advertiser for preventing noise caused by reflection of a signal between the first amplifier stage and the second amplifier stage, and the second amplifier stage and the output stage. The method of claim 8, A long-wavelength erbium-doped fiber amplifier, characterized in that for using the optical cycle and the optical fiber grating to remove the amplified self-emitting noise light from the amplified light output from the second erbium-added fiber. In the optical amplifier, An input terminal to which an optical signal of a long wavelength band is input; A laser diode of 980 nm wavelength band which outputs an excitation light source of 980 nm wavelength band in a forward direction; A forward first wavelength division multiplexing combiner for wavelength division multiplexing and combining the input optical signal and an excitation light source; A laser diode of 1530 nm wavelength band which outputs an excitation light source having a 1530 nm wavelength band in a reverse direction; A second wavelength division multiplexing combiner for wavelength division multiplexing and combining the reverse excitation light source; Erbium-added optical fiber for amplifying the input optical signal in the inverted state having a high energy level by the forward and reverse excitation light source; And And an advertiser connected to the input terminal, the first wavelength division multiplexer, and the output terminal of the amplified signal light to prevent noise caused by reflection of the signal. In the optical amplifier of the two stage amplification structure, An input terminal into which an optical signal is input, a laser diode of a 980 nm wavelength band for generating an excitation light source of a 980 nm wavelength band, a first wavelength division multiplexing combiner for multiplexing and combining the input optical signal and an excitation light source, and the first wavelength division multiplexer A first amplifying stage consisting of a first erbium-doped optical fiber for amplifying the optical signal coupled in the unit; And A forward first laser diode for generating an excitation light source having a 1530 nm wavelength band, and a forward second wavelength division multiplexing combiner for combining an amplified light source amplified in the first erbium-doped optical fiber with an excitation light source having the 1530 nm wavelength band, and a 1530 nm wavelength laser beam. A reverse second laser diode for generating an excitation light source in a wavelength band, a reverse third wavelength division multiplexing coupler for coupling a reverse excitation light source in the 1530 nm wavelength band, and a second amplifying the forward excitation light source and a reverse excitation light source It comprises a second amplification stage made of erbium-added optical fiber, And an advertiser for preventing noise caused by reflection of a signal between the first amplifying stage and the second amplifying stage, and the second amplifying stage and the output stage.